Spatio‐temporal patterns of snow in the Catalan Pyrenees (NE Iberia)

In a warmer climate, significant variations in the snow regime are expected. Thus, it is crucial to better understand present‐day snow cover regime, its duration and thickness, in order to anticipate future changes. This work presents the first characterization of snow patterns in the Catalan Pyrene...

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Bibliographic Details
Published in:International journal of climatology 2021-10, Vol.41 (12), p.5676-5697
Main Authors: Bonsoms, Josep, Gonzalez, Sergi, Prohom, Marc, Esteban, Pere, Salvador‐Franch, Ferran, López‐Moreno, Juan I., Oliva, Marc
Format: Article
Language:English
Subjects:
Atmospheric circulation
Circulation types
Climate
climate variability
Daily precipitation
Elevation
Low frequencies
Low frequency
Pyrenees
Snow
Snow accumulation
Snow cover
Snow depth
Snowmelt
Teleconnection patterns
Weather types
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Summary:In a warmer climate, significant variations in the snow regime are expected. Thus, it is crucial to better understand present‐day snow cover regime, its duration and thickness, in order to anticipate future changes. This work presents the first characterization of snow patterns in the Catalan Pyrenees based on 11 snow stations located in high elevation areas (>2,000 m). Here, we examine spatio‐temporal evolution of the daily snow depth and new snow height (HN) since the earliest 2000s to 2020. In addition, we analyse the different synoptic patterns that cause HN events in the study area as well as the low frequency climate modes on the different stages of the snow season. Our results show evidence that the measured snow amount differs considerably between the western and the eastern Catalan Pyrenees independently of the considered elevation. While the eastern part has an average seasonal cumulative HN of 278 cm, the western sector gets almost twice (433 cm). Nonetheless, the onset of the snow melting does not show substantial differences, being primarily ruled by the elevation in both areas. The longest snow records (Núria, 1971 m) point to an increase of HN from 1985 to 2020, a trend which is also observed in most stations from 2000 to 2020. Nevertheless, some stations of the N western fringe record negative trends associated with the low frequency variability of the Western Mediterranean Oscillation (WeMO). Results also indicate that the NW Atlantic low‐pressure systems are the circulation weather types that provide more abundant HN in the majority of snow stations. The Atlantic advections are more frequent in autumn and winter, while the Mediterranean advections provide more intense and recurrent HN in spring. The atmospheric circulation is basically ruled by the East Atlantic/West Russia and the WeMO teleconnection patterns. This work presents the first characterization of snow patterns in high elevation areas (>2,000 m) of the Catalan (SE) Pyrenees. We analyse the different synoptic patterns that cause new snow height events as well as the impact of the modes of low frequency climate. The longest snow records point to an increase of new snow height (from 1985 to 2020). Nevertheless, some stations of the N western fringe record negative trends associated with the frequency variability of the circulation weather types.
ISSN:0899-8418
1097-0088
DOI:10.1002/joc.7147